Integrated two-dimensional planar optical phased array

What is claimed is: 1. An optical phased array comprising: a first array of N optical signal emitters, N being an integer greater than or equal to 2; and a first array of M optical signal delay elements, each optical signal delay element being associated with and disposed between a different pair of optical signal emitters and operative to cause a phase/delay shift between optical signals emitted from its associated pair of optical signal emitters in response to a first input optical signal received by the optical phased array, wherein M is an integer greater than or equal to one. 2. The optical phased array of claim 1 wherein the phase/delay caused by each of the M optical signal delay elements is variable. 3. The optical phased array of claim 2 wherein the delays caused by at least a subset of the M optical signal phase/delay elements are varied so as to change an angle of an optical signal generated due to interference between one or more of N optical signals emitted by the N optical signal emitters. 4. The optical phased array of claim 3 wherein each of the M optical signal phase/delay elements is a ring resonator. 5. The optical phased array of claim 4 wherein each of the M optical ring resonators is a p-i-n junction operative to cause a phase/delay shift in response to an applied bias. 6. The optical phased array of claim 3 wherein each of the N optical signal emitters is an optical grating comprising a plurality of grooves. 7. The optical phased array of claim 6 wherein groove lengths of the N optical gratings are selected so as to increase along a direction of travel of the first input optical signal through the optical phase array. 8. The optical phased array of claim 7 wherein the groove lengths of the N optical gratings are selected so as to achieve a substantially similar intensity for the N emitted optical signals. 9. The optical phased array of claim 1 further comprising: a second array of N optical signal emitters formed parallel to the first array of the N optical signal emitters; and a second array of M optical signal delay elements, each optical signal delay element of the second array being associated with and disposed between a different pair of optical signal emitters of the second array and operative to cause a phase/delay shift between optical signals emitted from its associated pair of optical signal emitters in response to a second input optical signal received by the optical phased array. 10. The optical phased array of claim 9 wherein the N optical signals emitted from the first array of N optical signal emitters and the N optical signals emitted from the second array N of optical signal emitters have substantially similar wavelengths. 11. The optical phased array of claim 1 wherein the first array of N optical signal emitters and the first array of M optical signal delay elements are formed in a same semiconductor substrate. 12. The optical phased array of claim 9 wherein the first and second arrays of N optical signal emitters, and the first and second arrays of the M optical signal delay elements are formed in a same semiconductor substrate. 13. The optical phased array of claim 9 wherein said first input optical and second input optical signals are derived from a same source of optical signal. 14. The optical phased array of claim 1 wherein the first array of N optical signal emitters and the first array of M optical signal delay elements are formed in a same semiconductor substrate, and wherein the optical phased array further comprises: a second array of N optical signal emitters; and a second array of M optical signal delay elements, each optical signal delay element of the second array being associated with and disposed between a different pair of optical signal emitters of the second array and adapted to cause a phase/delay shift between optical signals emitted from its associated pair of optical signal emitters in response to a second input optical signal received by the optical phased array, and wherein the second array of N optical signal emitters is formed either above or below the first array of the N optical signal emitters. 15. The optical phased array of claim 1 wherein the optical signals emitted by the first array of N optical signal emitters are substantially parallel to a surface of a substrate in which the first array of N optical signal emitters and the first array of M optical signal delay elements are formed. 16. The optical phased array of claim 1 wherein the optical signals emitted by the first array of N optical signal emitters are substantially perpendicular to a surface of a substrate in which the first array of N optical signal emitters and the first array of M optical signal delay elements are formed. 17. A method of generating N optical signals of an optical phased array, N being an integer greater than or equal to 2, the method comprising: forming a first array of N optical signal emitters; and forming a first array of M optical signal delay elements, each optical signal delay element being associated with and disposed between a different pair of optical signal emitters and operative to cause a phase/delay shift between optical signals emitted from its associated pair of optical signal emitters in response to a first input optical signal received by the optical phased array, wherein M is an integer greater than or equal to one. 18. The method of claim 17 further comprising: varying a delay across one or more of the M optical signal phase/delay elements. 19. The method of claim 18 further comprising: varying a delay across at least a first subset of the M optical signal delay elements so as to change an angle of an optical signal generated due to interference between one or more of N optical signals emitted by the N optical signal emitters. 20. The method of claim 19 wherein each of the M optical signal phase/delay elements is a ring resonator. 21. The method of claim 20 wherein each of the M optical ring resonators is a p-i-n junction operative to cause a phase/delay shift in response to an applied bias. 22. The method of claim 19 wherein each of the N optical signal emitters is an optical grating comprising a plurality of grooves. 23. The method of claim 22 further comprising: selecting groove lengths of the N optical gratings in an increasing order along a direction of travel of the first input optical signal through the optical phase array. 24. The method of claim 23 further comprising: selecting the groove lengths of the N optical gratings such that intensities of the N emitted optical signals are substantially similar. 25. The method of claim 17 further comprising: forming a second array of N optical signal emitters parallel to the first array of the N optical signal emitters; and forming a second array of M optical signal delay elements, each optical signal delay element of the second array being associated with and disposed between a different pair of optical signal emitters of the second array and operative to cause a phase/delay shift between optical signals emitted from its associated pair of optical signal emitters in response to a second input optical signal received by the optical phased array. 26. The method of claim 25 wherein the N optical signals emitted from the first array of N optical signal emitters and the N optical signals emitted from the second array N of optical signal emitters ha